US20220200827A1 - Asymmetric Optical Communication Architecture - Google Patents
Asymmetric Optical Communication Architecture Download PDFInfo
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- US20220200827A1 US20220200827A1 US17/127,898 US202017127898A US2022200827A1 US 20220200827 A1 US20220200827 A1 US 20220200827A1 US 202017127898 A US202017127898 A US 202017127898A US 2022200827 A1 US2022200827 A1 US 2022200827A1
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- integrated circuit
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L25/00—Baseband systems
- H04L25/02—Details ; arrangements for supplying electrical power along data transmission lines
- H04L25/03—Shaping networks in transmitter or receiver, e.g. adaptive shaping networks
- H04L25/03878—Line equalisers; line build-out devices
- H04L25/03885—Line equalisers; line build-out devices adaptive
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L25/00—Baseband systems
- H04L25/02—Details ; arrangements for supplying electrical power along data transmission lines
- H04L25/0264—Arrangements for coupling to transmission lines
- H04L25/0272—Arrangements for coupling to multiple lines, e.g. for differential transmission
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N7/00—Television systems
- H04N7/22—Adaptations for optical transmission
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B10/00—Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
- H04B10/25—Arrangements specific to fibre transmission
- H04B10/2589—Bidirectional transmission
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B10/00—Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
- H04B10/40—Transceivers
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L25/00—Baseband systems
- H04L25/02—Details ; arrangements for supplying electrical power along data transmission lines
- H04L25/03—Shaping networks in transmitter or receiver, e.g. adaptive shaping networks
- H04L25/03006—Arrangements for removing intersymbol interference
- H04L25/03012—Arrangements for removing intersymbol interference operating in the time domain
- H04L25/03019—Arrangements for removing intersymbol interference operating in the time domain adaptive, i.e. capable of adjustment during data reception
- H04L25/03057—Arrangements for removing intersymbol interference operating in the time domain adaptive, i.e. capable of adjustment during data reception with a recursive structure
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L25/00—Baseband systems
- H04L25/02—Details ; arrangements for supplying electrical power along data transmission lines
- H04L25/03—Shaping networks in transmitter or receiver, e.g. adaptive shaping networks
- H04L25/03006—Arrangements for removing intersymbol interference
- H04L25/03343—Arrangements at the transmitter end
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N5/00—Details of television systems
- H04N5/76—Television signal recording
- H04N5/765—Interface circuits between an apparatus for recording and another apparatus
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N7/00—Television systems
- H04N7/015—High-definition television systems
Definitions
- the invention relates to an optical communication circuit, and in particular, but not exclusively, to an optical communication circuit with asymmetric optical communication architecture.
- optical fiber has been widely used for transmitting video signals or other high data rate signals.
- conventional cable uses copper wire to transfer video data or control data, which has limited bandwidth and is susceptible to noise or interference.
- the present invention proposes a better solution to overcome the above-mentioned problems.
- One objective of the present invention is to provide a single-chip integrated circuit with asymmetric optical Communication architecture to provide cost effective and power efficient solution for AOC (Active Optical Cable) applications.
- the present invention discloses a single-chip integrated circuit, comprising: at least one first unidirectional communication channel, wherein the first unidirectional communication channel comprises a first sub-circuit for converting a first electrical signal to a first optical signal; and at least one first bidirectional communication channel, wherein the first bidirectional communication channel comprises a second sub-circuit for converting a second electrical signal to a second optical signal and a third sub-circuit for converting a third optical signal to a third electrical signal.
- the first unidirectional communication channel is used for transmitting video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the video data.
- the first electrical signal is a single-ended signal.
- the first electrical signal is a pair of differential signals.
- the second electrical signal is a single-ended signal.
- the second electrical signal is a pair of differential signals.
- the third electrical signal is a single-ended signal.
- the third electrical signal is a pair of differential signals.
- the pair of differential signals is a TMDS (Time Minimized Differential Signal).
- an optical diode used to convert the first electrical signal to the first optical signal is outside the single-chip integrated circuit.
- an optical diode used to convert the first electrical signal to the first optical signal is inside the single-chip integrated circuit.
- an optical diode used to convert the second electrical signal to the second optical signal is outside the single-chip integrated circuit.
- an optical diode used to convert the second electrical signal to the second optical signal is inside the single-chip integrated circuit.
- a photo diode used to convert the third optical signal to the third electrical signal is outside the single-chip integrated circuit.
- a photo diode used to convert the third optical signal to the third electrical signal is inside the single-chip integrated circuit.
- the first unidirectional communication channel is used for transmitting High Definition Multimedia Interface (HDMI) video data and the at least one bidirectional communication channel is used for transmitting and receiving control data associated with the HDMI video data.
- HDMI High Definition Multimedia Interface
- the first unidirectional communication channel is used for transmitting Display Port (DP) video data and the at least one bidirectional communication channel is used for transmitting and receiving control data associated with the DP video data.
- DP Display Port
- each of the second electrical signal and the third electrical signal is based on USB standard.
- the single-chip integrated circuit is based on CMOS technology.
- the single-chip integrated circuit comprises a plurality of unidirectional communication channels, wherein each unidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal.
- the single-chip integrated circuit comprises a plurality of bidirectional communication channels, wherein each bidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a corresponding third sub-circuit for converting a corresponding optical signal to a corresponding electrical signal.
- the present invention discloses a single-chip integrated circuit, comprising: at least one first unidirectional communication channel, wherein the first unidirectional communication channel comprises a first sub-circuit for converting a corresponding optical signal to a corresponding electrical signal; and at least one first bidirectional communication channel, wherein the first bidirectional communication channel comprises a second sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a third sub-circuit for converting a corresponding optical signal to a corresponding electrical signal.
- a photo diode used to convert the first optical signal to the first electrical signal is outside the single-chip integrated circuit.
- a photo diode used to convert the first optical signal to the first electrical signal is inside the single-chip integrated circuit.
- an optical diode used to convert the second electrical signal to the second optical signal is outside the single-chip integrated circuit.
- an optical diode used to convert the second electrical signal to the second optical signal is inside the single-chip integrated circuit.
- a photo diode used to convert the third optical signal to the third electrical signal is outside the single-chip integrated circuit.
- a photo diode used to convert the third optical signal to the third electrical signal is inside the single-chip integrated circuit.
- the first unidirectional communication channel is used for receiving video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the video data.
- the first unidirectional communication channel is used for receiving HDMI video data and the at least one bidirectional communication channel is used for transmitting and receiving control data associated with the HDMI video data.
- the first unidirectional communication channel is used for receiving DP video data and the at least one bidirectional communication channel is used for transmitting and receiving control data associated with the DP video data.
- each of the second electrical signal and the third electrical signal is based on USB standard.
- the single-chip integrated circuit is based on CMOS technology.
- the present invention discloses a circuit with asymmetric optical communication architecture, comprising: at least one first unidirectional communication channel, wherein the first unidirectional communication channel comprises a first sub-circuit for converting a first electrical signal to a first optical signal; and at least one first bidirectional communication channel, wherein the first bidirectional communication channel comprises a second sub-circuit for converting a second electrical signal to a second optical signal and a third sub-circuit for converting a third optical signal to a third electrical signal, wherein the first unidirectional communication channel is used for transmitting video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the video data.
- the circuit comprises a plurality of unidirectional communication channels and a plurality of bidirectional communication channels, wherein each unidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal, and wherein each bidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a corresponding third sub-circuit for converting a corresponding optical signal to a corresponding electrical signal.
- the present invention discloses a communication system, comprising: a first single-chip integrated circuit, comprising: at least one first unidirectional communication channel, wherein each unidirectional communication channel comprises a first sub-circuit for converting a corresponding electrical signal to a corresponding optical signal; and at least one first bidirectional communication channel, wherein each bidirectional communication channel comprises a corresponding second sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a third sub-circuit for converting a corresponding optical signal to a corresponding electrical signal; and a second single-chip integrated circuit, comprising: at least one second unidirectional communication channel, wherein each unidirectional communication channel comprises a first sub-circuit for converting a corresponding optical signal to a corresponding electrical signal; and at least one second bidirectional communication channel, wherein each bidirectional communication channel comprises a corresponding second sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a third sub-circuit for converting a corresponding optical signal to
- FIG. 1A illustrates a single-chip integrated circuit with asymmetric optical communication architecture in accordance with one embodiment of the present invention
- FIG. 1B illustrates a single-chip integrated circuit with asymmetric optical communication architecture in accordance with one embodiment of the present invention
- FIG. 1C illustrates a sub-circuit of the unidirectional communication channel of FIG. 1A in accordance with one embodiment of the present invention
- FIG. 1D illustrates a sub-circuit of the bidirectional communication channel of FIG. 1A in accordance with one embodiment of the present invention
- FIG. 2 illustrates one example of the single chip in FIG. 1A in accordance with one embodiment of the present invention
- FIG. 3A illustrates a single-chip integrated circuit with asymmetric optical communication architecture in accordance with another embodiment of the present invention
- FIG. 3B illustrates a single-chip integrated circuit with asymmetric optical communication architecture in accordance with another embodiment of the present invention
- FIG. 3C illustrates a sub-circuit of unidirectional communication channel of FIG. 3A in accordance with one embodiment of the present invention
- FIG. 3D illustrates a sub-circuit of bidirectional communication channel of FIG. 3A in accordance with one embodiment of the present invention
- FIG. 4 illustrates one example of the single chip in FIG. 3A in accordance with one embodiment of the present invention
- FIG. 5 illustrates an example of a communication system using the single-chip integrated circuit in FIG. 1A and the single-chip integrated circuit in FIG. 3A ;
- FIG. 6 illustrates an example of a communication system using the single-chip integrated circuit in FIG. 1A and the single-chip integrated circuit in FIG. 3A ;
- FIG. 7 illustrates an example of a communication system using the single-chip integrated circuit in FIG. 1A and the single-chip integrated circuit in FIG. 3A ;
- FIG. 8 illustrates an example of a communication system using the single-chip integrated circuit in FIG. 1A and the single-chip integrated circuit in FIG. 3A ;
- FIG. 9 illustrates an example of a communication system using the single-chip integrated circuit in FIG. 1A and the single-chip integrated circuit in FIG. 3A .
- HDMI and DP interface grows together with USB 3.1/3.2.
- HDMI 2.1 AOC Active Optical Cable
- 4K display when the distance is longer than 5 meters
- 8K display when the distance is longer than 1 meter.
- AOC can overcome long distance video display applications.
- Combination of HDMI/DP and USB optical cable is suitable for emerging applications like VR headset or NB docking stations.
- HDMI active optical cable provides fast and high-quality video for various applications for indoor/outdoor digital signage, 4K/8K TV, medical image display, or gaming console applications.
- a single-chip integrated circuit with asymmetric optical communication architecture of the present invention can provide a cost effective and power efficient solution for AOC industry.
- FIG. 1A illustrates a single-chip integrated circuit 100 with asymmetric optical communication architecture, wherein single-chip integrated circuit 100 comprises: at least one first unidirectional communication channel 101 , wherein the first unidirectional communication channel 101 comprises a first sub-circuit for converting a first electrical signal 101 a to a first optical signal 101 b ; and at least one first bidirectional communication channel 102 , wherein the first bidirectional communication channel comprises a second sub-circuit for converting a second electrical signal 102 a to a second optical signal 102 b and a third sub-circuit for converting a third optical signal 102 c to a third electrical signal 102 d.
- the first electrical signal 101 a is a single-ended signal, wherein a pin of the single-chip integrated circuit 100 is used for inputting the first electrical signal 101 a.
- the first electrical signal 101 a is a pair of differential signals, wherein two pins of the single-chip integrated circuit 100 are used for inputting the pair of differential signals.
- the second electrical signal 102 a is a single-ended signal, wherein a pin of the single-chip integrated circuit 100 is used for inputting the second electrical signal 102 a.
- the second electrical signal 102 a is a pair of differential signals, wherein two pins of the single-chip integrated circuit 100 are used for inputting the pair of differential signals.
- the third electrical signal 102 d is a single-ended signal, wherein a pin of the single-chip integrated circuit 100 is used for outputting the third electrical signal 102 d.
- the third electrical signal 102 d is a pair of differential signals, wherein two pins of the single-chip integrated circuit 100 are used for outputting the pair of differential signals.
- the pair of differential signals is based on TMDS (Time Minimized Differential Signal) and conformed to HDMI standard.
- TMDS Time Minimized Differential Signal
- the pair of differential signals is based on TMDS (Time Minimized Differential Signal) and conformed to DP standard.
- TMDS Time Minimized Differential Signal
- each of the second electrical signal 102 a and the third electrical signal 102 d is a single-ended signal.
- each of the second electrical signal 102 a and the third electrical signal 102 d is a pair of differential signals.
- the second electrical signal 102 a and the third electrical signal 102 d are based on USB standard.
- an optical diode D 1 such as a laser diode, is used for converting the first electrical signal 101 a to the first optical signal 101 b.
- the optical diode D 1 is outside of the single-chip integrated circuit 100 .
- the optical diode D 1 is inside of the single-chip integrated circuit 100 .
- the optical diode D 1 is a VCSEL (Vertical Cavity Surface Emitting Laser) diode.
- an optical diode D 2 such as a laser diode, is used for converting the second electrical signal 102 a to the second optical signal 102 b and a photo diode D 3 is used for converting the third optical signal 102 c to the third electrical signal 102 d.
- the optical diode D 2 is a VCSEL (Vertical Cavity Surface Emitting Laser) diode.
- the diodes D 2 and D 3 are outside of the integrated circuit 100 .
- the diodes D 2 and D 3 are inside of the integrated circuit 100 .
- the at least one unidirectional communication channel 101 is used for transmitting video data and the at least one bidirectional communication channel 102 is used for transmitting and receiving control data associated with the video data.
- the at least one unidirectional communication channel 101 is used for transmitting HDMI video data and the at least one bidirectional communication channel 102 is used for transmitting and receiving HDMI control data associated with the HDMI video data.
- the at least one unidirectional communication channel 101 is used for transmitting DP video data and the at least one bidirectional communication channel 102 is used for transmitting and receiving DP control data associated with the DP video data.
- the single-chip integrated circuit 100 is based on CMOS technology.
- the single-chip integrated circuit 100 comprises a plurality of unidirectional communication channels, wherein each unidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal.
- the single-chip integrated circuit 100 comprises a plurality of bidirectional communication channels, wherein each bidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a corresponding sub-circuit for converting a corresponding optical signal to a corresponding electrical signal.
- each unidirectional communication channel 101 transmits 12 Gbps signal.
- each unidirectional communication channel 101 transmits 6 Gbps signal.
- each bidirectional communication channel 102 transmits and receives 480 Mbps signal.
- each bidirectional communication channel 102 transmits and receives 10 Gbps signal.
- each bidirectional communication channel 102 transmits and receives 20 Gbps signal.
- the single-chip integrated circuit 100 comprises four unidirectional communication channels and one bidirectional communication channel.
- the single-chip integrated circuit 100 comprises four unidirectional communication channels and two bidirectional communication channels.
- the first unidirectional communication channel 101 comprises a first equalizer 101 E and a first output driver 101 D, wherein the first electrical signal 101 a is coupled to an input of the first equalizer 101 E and an output of the first equalizer 101 E is coupled to an input of the first output driver 101 D, wherein the first output driver 101 D is coupled to a first optical diode D 1 to generate the first optical signal 101 b.
- the first bidirectional communication channel 102 comprises a first equalizer 102 E and a first output driver 102 D, wherein the first electrical signal 102 a is coupled to an input of the first equalizer 102 E and an output of the first equalizer 102 E is coupled to an input of the first output driver 102 D, wherein the first output driver 102 D is coupled to a second optical diode D 2 to generate the second optical signal 102 b.
- the first bidirectional communication channel 102 comprises an amplifier 102 A, wherein an input of the amplifier 102 A is coupled to a fourth electrical signal that is generated by the optical diode D 3 in response to the third optical signal 102 c , and an output of the amplifier 102 A is coupled to the third electrical signal 102 d.
- the first bidirectional communication channel 102 further comprises an input buffer 102 B 1 and an output buffer 102 B 2 , wherein an input of the input buffer 102 B 1 is coupled to the fourth electrical signal generated by the optical diode D 3 in response to the third optical signal 102 c , and an output of the input buffer 102 B 1 is coupled to the input of the amplifier 102 A, wherein an input of the output buffer 102 B 2 is coupled to the output of the amplifier 102 A, and an output of the output buffer 102 A is coupled to the third electrical signal 102 d.
- FIG. 2 illustrates an example of the single-chip integrated circuit 100 , wherein the first unidirectional communication channel receives a pair of differential signals D 1 _in + , D 1 _in ⁇ that is coupled to a first equalizer 101 E, wherein the first equalizer 101 E is inputted to a first output driver 101 D and the first output driver 101 D outputs a first pair of differential signal VCSEL 1 , CC 1 to drive a first laser diode LD 1 ; the second unidirectional communication channel receives a second pair of differential signals D 2 _in + , D 2 _in ⁇ that is coupled to a second equalizer, wherein the second equalizer is inputted to a second output driver and the second output driver outputs a second pair of differential signal VCSEL 2 , CC 2 to drive a second laser diode LD 2 ; the third unidirectional communication channel receives a third pair of differential signals D 3 _in + , D 3 _in ⁇ that is coupled to a third equalizer, where
- the first bidirectional communication channel receives a pair of differential signals D 5 _in + , D 5 _in ⁇ that is coupled to a fifth equalizer, wherein the fifth equalizer is inputted to a fifth output driver and the fifth output driver outputs a fifth pair of differential signal VCSEL 5 , CC 5 to drive a fifth laser diode LD 5 ;
- the first bidirectional communication channel receives a pair of differential signals PINK 6 , PINA 6 that is generated form the photo diode PD 6 and coupled to an input buffer, wherein the input buffer 102 B 1 is inputted to an input of an amplifier 102 A and an output of the amplifier 102 A is inputted to an output buffer 102 B 2 , wherein the output buffer 102 B 2 outputs a sixth pair of differential signals D 6 _in + , D 6 _in ⁇ .
- each of the laser diodes D 1 , D 2 , D 3 , D 4 , D 5 is a VCSEL (Vertical Cavity Surface Emitting Laser) diode.
- the single-chip integrated circuit in FIG. 2 is based on CMOS technology.
- FIG. 3A illustrates a single-chip integrated circuit 300 , wherein single-chip integrated circuit 300 comprises: at least one first unidirectional communication channel 301 , wherein the first unidirectional communication channel 301 comprises a first sub-circuit for converting a first optical signal 301 b to a first electrical signal 301 a ; and at least one first bidirectional communication channel 302 , wherein the first bidirectional communication channel comprises a second sub-circuit for converting a second electrical signal 302 a to a second optical signal 302 b and a third sub-circuit for converting a third optical signal 302 c to a third electrical signal 302 d.
- a pin of the single-chip integrated circuit 300 is used for outputting the first electrical signal 301 a , wherein the first electrical signal 301 a is a single-ended signal.
- the first electrical signal 301 a is a pair of differential signals, wherein two pins of the single-chip integrated circuit 300 are used for outputting the pair of differential signals.
- the pair of differential signals is based on TMDS (Time Minimized Differential Signal) and conformed to HDMI standard.
- TMDS Time Minimized Differential Signal
- the pair of differential signals is based on TMDS (Time Minimized Differential Signal) and conformed to DP standard.
- TMDS Time Minimized Differential Signal
- the second electrical signal 302 a and the third electrical signal 302 d are based on USB standard.
- each of the second electrical signal 302 a and the third electrical signal 302 d is a single-ended signal.
- each of the second electrical signal 302 a and the third electrical signal 302 d is a pair of differential signals.
- a photo diode D 4 used for converting the first optical signal 301 b to the first electrical signal 301 a is outside of the single-chip integrated circuit 300 .
- the photo diode D 4 used for converting the first optical signal 301 b to the first electrical signal 301 a is inside of the single-chip integrated circuit 300 .
- an optical diode D 2 such as a laser diode, is used for converting the second electrical signal 302 a to the second optical signal 302 b and a photo diode D 3 is used for converting the third optical signal 302 c to the third electrical signal 302 d.
- the optical diode D 2 is a VCSEL (Vertical Cavity Surface Emitting Laser) diode.
- the diodes D 2 and D 3 are outside of the integrated circuit 300 .
- the diodes D 2 and D 3 are inside of the integrated circuit 300 .
- the first unidirectional communication channel is used for transmitting video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the video data.
- the at least one unidirectional communication channel is used for transmitting HDMI video data and the at least one bidirectional communication channel is used for transmitting and receiving HDMI control data associated with the HDMI video data.
- the at least one unidirectional communication channel is used for transmitting DP video data and the at least one bidirectional communication channel is used for transmitting and receiving DP control data associated with the DP video data.
- the single-chip integrated circuit 300 is based on CMOS technology.
- the single-chip integrated circuit 300 comprises a plurality of unidirectional communication channels.
- the single-chip integrated circuit 300 comprises a plurality of bidirectional communication channels.
- the unidirectional communication channel 301 receives 12 Gbps optical signal.
- the unidirectional communication channel 301 receives 6 Gbps optical signal.
- the bidirectional communication channel 302 transmits and receives 480 Mbps optical signal.
- the bidirectional communication channel 302 transmits and receives 10 Gbps optical signal.
- the bidirectional communication channel 302 transmits and receives 20 Gbps optical signal.
- the single-chip integrated circuit 300 comprises four unidirectional communication channels and one bidirectional communication channel.
- the single-chip integrated circuit 300 comprises four unidirectional communication channels and two bidirectional communication channels.
- the first unidirectional communication channel 301 comprises an amplifier 301 A, wherein an input of the amplifier 301 A is coupled to a fourth electrical signal 301 e that is generated by a photo diode D 4 in response to the first optical signal 301 b , and an output of the amplifier 301 A is coupled to the first electrical signal 301 a.
- the first bidirectional communication channel 301 further comprises an input buffer 301 B 1 and an output buffer 301 B 2 , wherein an input of the input buffer 301 B 1 is coupled to the fourth electrical signal 301 e that is generated by the photo diode D 4 in response to the first optical signal 301 b , and an output of the input buffer 301 B 1 is coupled to the input of the amplifier 301 A, wherein an input of the output buffer 301 B 2 is coupled to the output of the amplifier 301 A, and an output of the output buffer 301 B 2 is coupled to first electrical signal 301 a.
- the first bidirectional communication channel 302 comprises a first equalizer 302 E and a first output driver 302 D, wherein the first electrical signal 302 a is coupled to an input of the first equalizer 302 E and an output of the first equalizer 302 E is coupled to an input of the first output driver 302 D, wherein the first output driver 302 D is coupled to a second optical diode D 2 to generate the second optical signal 302 b.
- the first bidirectional communication channel 302 comprises an amplifier 302 A, wherein an input of the amplifier 302 A is coupled to an electrical signal 302 e that is generated by the photo diode D 3 in response to the third optical signal 302 c , and an output of the amplifier 302 A is coupled to the third electrical signal 302 d.
- the first bidirectional communication channel 302 further comprises an input buffer 302 B 1 and an output buffer 302 B 2 , wherein an input of the input buffer 302 B 1 is coupled to the electrical signal 302 e that is generated by the photo diode D 3 in response to the third optical signal 302 c , and an output of the input buffer 302 B 1 is coupled to the input of the amplifier 302 A, wherein an input of the output buffer 302 B 2 is coupled to the output of the amplifier 302 A, and an output of the output buffer 302 A is coupled to the third electrical signal 302 d.
- FIG. 4 illustrates an example of the single-chip integrated circuit 300 , wherein the first unidirectional communication channel receives a pair of differential signals PINK 1 , PINA 1 generated form the photo diode PD 1 and coupled to an input buffer 301 B 1 , wherein the input buffer 301 B 1 is inputted to an input of an amplifier 301 A and an output of the amplifier 301 A is inputted to an output buffer 301 B 2 , wherein the output buffer 301 B 2 outputs a pair of differential signals out 1 + , out 1 ⁇ ; the second unidirectional communication channel receives a pair of differential signals PINK 2 , PINA 2 generated form the photo diode PD 2 and coupled to an input buffer, wherein the input stage buffer is inputted to an input of an amplifier and an output of the amplifier is inputted to an output buffer, wherein the output buffer outputs a pair of differential signals out 2 + , out 2 ; the third unidirectional communication channel receives a pair of differential signals PINK 3 , PINA 3 generated form
- the first bidirectional communication channel receives a pair of differential signals PINK 5 , PINA 5 generated form the photo diode PD 5 and coupled to an input buffer 302 B 1 , wherein the input buffer 302 B 1 is inputted to an input of an amplifier 302 A and an output of the amplifier 302 A is inputted to an output buffer 302 B 2 , wherein the output buffer 302 B 2 outputs a pair of differential signals out 5 + , out 5 ⁇ ; the first bidirectional communication channel receives a pair of differential signals D 6 _in + , D 6 _in ⁇ that is coupled to an equalizer 302 E, wherein the equalizer 302 E is inputted to an output driver 302 D and the output driver 302 D outputs a pair of differential signal VCSEL 6 , CC 6 to drive the laser diode LD 6 .
- each laser diode LD 1 , LD 2 , LD 3 , LD 4 , LD 6 is a VCSEL (Vertical Cavity Surface Emitting Laser) diode.
- FIG. 5 illustrates an example of a communication system using the single-chip integrated circuit 100 and the single-chip integrated circuit 300 , wherein the single-chip integrated circuit 100 and the single-chip integrated circuit 300 are connected by six fibers, wherein the four unidirectional channel of the single-chip integrated circuit 100 are used for transmitting HDMI TMDS video, and the four unidirectional channel of the single-chip integrated circuit 300 are used for receiving the HDMI TMDS video.
- the USB bidirectional channel of the single-chip integrated circuit 100 and the USB bidirectional channel of the single-chip integrated circuit 300 are used for transmitting and receiving control data associated with the HDMI TMDS video data.
- the four unidirectional HDMI TMDS channels can be 4 ⁇ 6 Gbps (HDMI 2.0) or 4 ⁇ 12 Gbps (HDMI 2.1).
- the USB bidirectional channel can be 1 ⁇ 480 Mbps (USB 2) or 1 ⁇ 10 G bps (USB 3) or 1 ⁇ 20 G bps (USB 4).
- the advantages of FIG. 6 includes: Low cost AOC with minimum VCSEL/PD chip count, designed for cost effective 6 fiber cable application, free from EMI interference, high bandwidth, low signal loss, which is suitable for applications such as NB docking station, high speed light weight VR headset or gaming console connection.
- FIG. 6 illustrates an example of a communication system using the single-chip integrated circuit 100 and the single-chip integrated circuit 300 , wherein the single-chip integrated circuit 100 and the single-chip integrated circuit 300 are connected by six fibers, wherein the four DP TMDS unidirectional channel of the single-chip integrated circuit 100 , are used for transmitting DP video data, and the four DP TMDS unidirectional channel of the single-chip integrated circuit 300 are used for receiving the DP video data.
- the USB bidirectional channel of the single-chip integrated circuit 100 and the USB bidirectional channel of the single-chip integrated circuit 300 are used for transmitting and receiving control data associated with the DP video data.
- the four DP TMDS unidirectional channels can be 8.1 Gbps (DP1.4) or 4 ⁇ 20 Gbps (DP2.0).
- the USB bidirectional channel can be 1 ⁇ 480 Mbps (USB 2) or 1 ⁇ 10 G bps (USB 3) or 1 ⁇ 20 G bps (USB 4).
- the advantages of the communication system in FIG. 7 includes: low cost AOC with minimum VCSEL/PD chip count, designed for cost effective 6 fiber cable application, free from EMI interference, high bandwidth, low signal loss, which is suitable for applications such as NB docking station, high speed light weight VR headset or gaming console connection.
- FIG. 7 illustrates an example of a communication system using the single-chip integrated circuit 100 and the single-chip integrated circuit 300 , wherein the single-chip integrated circuit 100 and the single-chip integrated circuit 300 are connected by six fibers, wherein the four unidirectional channel of the single-chip integrated circuit 100 are used for transmitting HDMI TMDS video, and the four unidirectional channel of the single-chip integrated circuit 300 are used for receiving the HDMI TMDS video.
- Two USB bidirectional channels of the single-chip integrated circuit 100 and the two USB bidirectional channel of the single-chip integrated circuit 300 are used for transmitting and receiving control data associated with the HDMI TMDS video data.
- the four HDMI TMDS unidirectional channels can be 4 ⁇ 6 Gbps (HDMI 2.0) or 4 ⁇ 12 Gbps (HDMI 2.1).
- the two USB bidirectional channels can be 2 ⁇ 480 Mbps (USB 2) or 2 ⁇ 10 G bps (USB 3) or 2 ⁇ 20 G bps (USB 4).
- the advantages of the communication system in FIG. 8 includes: low cost AOC with minimum VCSEL/PD chip count, designed for cost effective 8 fiber cable application, free from EMI interference, high bandwidth, low signal loss, which is suitable for applications such as NB docking station, high speed light weight VR headset or gaming console connection.
- FIG. 8 illustrates an example of a communication system using the single-chip integrated circuit 100 and the single-chip integrated circuit 300 , wherein the single-chip integrated circuit 100 and the single-chip integrated circuit 300 are connected by six fibers, wherein the four unidirectional channel of the single-chip integrated circuit 100 are used for transmitting DP TMDS video, and the four unidirectional channel of the single-chip integrated circuit 300 are used for receiving the DP TMDS video.
- Two USB bidirectional channels of the single-chip integrated circuit 100 and the two USB bidirectional channel of the single-chip integrated circuit 300 are used for transmitting and receiving control data associated with the DP TMDS video data.
- the four DP TMDS unidirectional channels can be 4 ⁇ 8.1 Gbps (DP1.4) or 4 ⁇ 20 Gbps (DP2.0).
- the two USB bidirectional channels can be 2 ⁇ 480 Mbps (USB 2) or 2 ⁇ 10 G bps (USB 3) or 2 ⁇ 20 G bps (USB 4).
- the advantages of the communication system in FIG. 9 includes: low cost AOC with minimum VCSEL/PD chip count, designed for cost effective 8 fiber cable application, free from EMI interference, high bandwidth, low signal loss, which is suitable for applications such as NB docking station, high speed light weight VR headset or gaming console connection.
- FIG. 9 illustrates an example of a communication system using the single-chip integrated circuit 100 and the single-chip integrated circuit 300 , wherein the single-chip integrated circuit 100 and the single-chip integrated circuit 300 are connected by six fibers, wherein the four unidirectional channel of the single-chip integrated circuit 100 are used for transmitting HDMI TMDS video, and the four unidirectional channel of the single-chip integrated circuit 300 are used for receiving the HDMI TMDS video.
- Two USB bidirectional channels of the single-chip integrated circuit 100 and the two USB bidirectional channel of the single-chip integrated circuit 300 are used for transmitting and receiving control data associated with the HDMI TMDS video data.
- the four HDMI TMDS unidirectional channels can be 4 ⁇ 6 Gbps (HDMI 2.0) or 4 ⁇ 12 Gbps (HDMI 2.1).
- the two bidirectional channels includes one eARC bidirectional channel and one I2C bidirectional channel.
- the eARC bidirectional channel can be used for HDMI 2.1 eARC reverse audio signal transmission.
- the I2C bidirectional channel can be used for HDMI 2.1 I2C data transmission.
- the advantages of the communication system in FIG. 10 includes: low cost AOC with minimum VCSEL/PD chip count, designed for cost effective 8 fiber cable application, free from EMI interference, high bandwidth, low signal loss, which is suitable for optical HDMI 2.1 AOC application.
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Abstract
A single-chip integrated circuit is disclosed, wherein the single-chip integrated circuit comprises at least one unidirectional communication channel for converting a first electrical signal to a first optical signal and at least one bidirectional communication channel for converting a second electrical signal to a second optical signal and converting a third optical signal to a third electrical signal.
Description
- The invention relates to an optical communication circuit, and in particular, but not exclusively, to an optical communication circuit with asymmetric optical communication architecture.
- In recent years, optical fiber has been widely used for transmitting video signals or other high data rate signals. However, conventional cable uses copper wire to transfer video data or control data, which has limited bandwidth and is susceptible to noise or interference.
- Accordingly, the present invention proposes a better solution to overcome the above-mentioned problems.
- One objective of the present invention is to provide a single-chip integrated circuit with asymmetric optical Communication architecture to provide cost effective and power efficient solution for AOC (Active Optical Cable) applications.
- The present invention discloses a single-chip integrated circuit, comprising: at least one first unidirectional communication channel, wherein the first unidirectional communication channel comprises a first sub-circuit for converting a first electrical signal to a first optical signal; and at least one first bidirectional communication channel, wherein the first bidirectional communication channel comprises a second sub-circuit for converting a second electrical signal to a second optical signal and a third sub-circuit for converting a third optical signal to a third electrical signal.
- In one embodiment, the first unidirectional communication channel is used for transmitting video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the video data.
- In one embodiment, the first electrical signal is a single-ended signal.
- In one embodiment, the first electrical signal is a pair of differential signals.
- In one embodiment, the second electrical signal is a single-ended signal.
- In one embodiment, the second electrical signal is a pair of differential signals.
- In one embodiment, the third electrical signal is a single-ended signal.
- In one embodiment, the third electrical signal is a pair of differential signals.
- In one embodiment, the pair of differential signals is a TMDS (Time Minimized Differential Signal).
- In one embodiment, an optical diode used to convert the first electrical signal to the first optical signal is outside the single-chip integrated circuit.
- In one embodiment, an optical diode used to convert the first electrical signal to the first optical signal is inside the single-chip integrated circuit.
- In one embodiment, an optical diode used to convert the second electrical signal to the second optical signal is outside the single-chip integrated circuit.
- In one embodiment, an optical diode used to convert the second electrical signal to the second optical signal is inside the single-chip integrated circuit.
- In one embodiment, a photo diode used to convert the third optical signal to the third electrical signal is outside the single-chip integrated circuit.
- In one embodiment, a photo diode used to convert the third optical signal to the third electrical signal is inside the single-chip integrated circuit.
- In one embodiment, the first unidirectional communication channel is used for transmitting High Definition Multimedia Interface (HDMI) video data and the at least one bidirectional communication channel is used for transmitting and receiving control data associated with the HDMI video data.
- In one embodiment, the first unidirectional communication channel is used for transmitting Display Port (DP) video data and the at least one bidirectional communication channel is used for transmitting and receiving control data associated with the DP video data.
- In one embodiment, each of the second electrical signal and the third electrical signal is based on USB standard.
- In one embodiment, the single-chip integrated circuit is based on CMOS technology.
- In one embodiment, the single-chip integrated circuit comprises a plurality of unidirectional communication channels, wherein each unidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal.
- In one embodiment, the single-chip integrated circuit comprises a plurality of bidirectional communication channels, wherein each bidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a corresponding third sub-circuit for converting a corresponding optical signal to a corresponding electrical signal.
- The present invention discloses a single-chip integrated circuit, comprising: at least one first unidirectional communication channel, wherein the first unidirectional communication channel comprises a first sub-circuit for converting a corresponding optical signal to a corresponding electrical signal; and at least one first bidirectional communication channel, wherein the first bidirectional communication channel comprises a second sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a third sub-circuit for converting a corresponding optical signal to a corresponding electrical signal.
- In one embodiment, a photo diode used to convert the first optical signal to the first electrical signal is outside the single-chip integrated circuit.
- In one embodiment, a photo diode used to convert the first optical signal to the first electrical signal is inside the single-chip integrated circuit.
- In one embodiment, an optical diode used to convert the second electrical signal to the second optical signal is outside the single-chip integrated circuit.
- In one embodiment, an optical diode used to convert the second electrical signal to the second optical signal is inside the single-chip integrated circuit.
- In one embodiment, a photo diode used to convert the third optical signal to the third electrical signal is outside the single-chip integrated circuit.
- In one embodiment, a photo diode used to convert the third optical signal to the third electrical signal is inside the single-chip integrated circuit.
- In one embodiment, the first unidirectional communication channel is used for receiving video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the video data.
- In one embodiment, the first unidirectional communication channel is used for receiving HDMI video data and the at least one bidirectional communication channel is used for transmitting and receiving control data associated with the HDMI video data.
- In one embodiment, the first unidirectional communication channel is used for receiving DP video data and the at least one bidirectional communication channel is used for transmitting and receiving control data associated with the DP video data.
- In one embodiment, each of the second electrical signal and the third electrical signal is based on USB standard.
- In one embodiment, the single-chip integrated circuit is based on CMOS technology.
- The present invention discloses a circuit with asymmetric optical communication architecture, comprising: at least one first unidirectional communication channel, wherein the first unidirectional communication channel comprises a first sub-circuit for converting a first electrical signal to a first optical signal; and at least one first bidirectional communication channel, wherein the first bidirectional communication channel comprises a second sub-circuit for converting a second electrical signal to a second optical signal and a third sub-circuit for converting a third optical signal to a third electrical signal, wherein the first unidirectional communication channel is used for transmitting video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the video data.
- In one embodiment, the circuit comprises a plurality of unidirectional communication channels and a plurality of bidirectional communication channels, wherein each unidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal, and wherein each bidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a corresponding third sub-circuit for converting a corresponding optical signal to a corresponding electrical signal.
- The present invention discloses a communication system, comprising: a first single-chip integrated circuit, comprising: at least one first unidirectional communication channel, wherein each unidirectional communication channel comprises a first sub-circuit for converting a corresponding electrical signal to a corresponding optical signal; and at least one first bidirectional communication channel, wherein each bidirectional communication channel comprises a corresponding second sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a third sub-circuit for converting a corresponding optical signal to a corresponding electrical signal; and a second single-chip integrated circuit, comprising: at least one second unidirectional communication channel, wherein each unidirectional communication channel comprises a first sub-circuit for converting a corresponding optical signal to a corresponding electrical signal; and at least one second bidirectional communication channel, wherein each bidirectional communication channel comprises a corresponding second sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a third sub-circuit for converting a corresponding optical signal to a corresponding electrical signal; wherein the first single-chip integrated circuit and the second single-chip integrated circuit are connected by optical fibers.
- The detailed technology and above preferred embodiments implemented for the present invention are described in the following paragraphs accompanying the appended drawings for people skilled in this field to well appreciate the features of the claimed invention.
- The foregoing aspects and many of the accompanying advantages of this invention will become more readily appreciated as the same becomes better understood by reference to the following detailed description when taken in conjunction with the accompanying drawings, wherein:
-
FIG. 1A illustrates a single-chip integrated circuit with asymmetric optical communication architecture in accordance with one embodiment of the present invention; -
FIG. 1B illustrates a single-chip integrated circuit with asymmetric optical communication architecture in accordance with one embodiment of the present invention; -
FIG. 1C illustrates a sub-circuit of the unidirectional communication channel ofFIG. 1A in accordance with one embodiment of the present invention; -
FIG. 1D illustrates a sub-circuit of the bidirectional communication channel ofFIG. 1A in accordance with one embodiment of the present invention; -
FIG. 2 illustrates one example of the single chip inFIG. 1A in accordance with one embodiment of the present invention; -
FIG. 3A illustrates a single-chip integrated circuit with asymmetric optical communication architecture in accordance with another embodiment of the present invention; -
FIG. 3B illustrates a single-chip integrated circuit with asymmetric optical communication architecture in accordance with another embodiment of the present invention; -
FIG. 3C illustrates a sub-circuit of unidirectional communication channel ofFIG. 3A in accordance with one embodiment of the present invention; -
FIG. 3D illustrates a sub-circuit of bidirectional communication channel ofFIG. 3A in accordance with one embodiment of the present invention; -
FIG. 4 illustrates one example of the single chip inFIG. 3A in accordance with one embodiment of the present invention; -
FIG. 5 illustrates an example of a communication system using the single-chip integrated circuit inFIG. 1A and the single-chip integrated circuit inFIG. 3A ; -
FIG. 6 illustrates an example of a communication system using the single-chip integrated circuit inFIG. 1A and the single-chip integrated circuit inFIG. 3A ; -
FIG. 7 illustrates an example of a communication system using the single-chip integrated circuit inFIG. 1A and the single-chip integrated circuit inFIG. 3A ; -
FIG. 8 illustrates an example of a communication system using the single-chip integrated circuit inFIG. 1A and the single-chip integrated circuit inFIG. 3A ; and -
FIG. 9 illustrates an example of a communication system using the single-chip integrated circuit inFIG. 1A and the single-chip integrated circuit inFIG. 3A . - The detailed explanation of the present invention is described as following. The described preferred embodiments are presented for purposes of illustrations and description, and they are not intended to limit the scope of the present invention.
- HDMI and DP interface grows together with USB 3.1/3.2. HDMI 2.1 AOC (Active Optical Cable) is required for 4K display when the distance is longer than 5 meters and 8K display when the distance is longer than 1 meter. AOC can overcome long distance video display applications. Combination of HDMI/DP and USB optical cable is suitable for emerging applications like VR headset or NB docking stations.
- HDMI active optical cable (AOC) provides fast and high-quality video for various applications for indoor/outdoor digital signage, 4K/8K TV, medical image display, or gaming console applications.
- A single-chip integrated circuit with asymmetric optical communication architecture of the present invention can provide a cost effective and power efficient solution for AOC industry.
-
FIG. 1A illustrates a single-chipintegrated circuit 100 with asymmetric optical communication architecture, wherein single-chipintegrated circuit 100 comprises: at least one firstunidirectional communication channel 101, wherein the firstunidirectional communication channel 101 comprises a first sub-circuit for converting a firstelectrical signal 101 a to a firstoptical signal 101 b; and at least one firstbidirectional communication channel 102, wherein the first bidirectional communication channel comprises a second sub-circuit for converting a secondelectrical signal 102 a to a secondoptical signal 102 b and a third sub-circuit for converting a thirdoptical signal 102 c to a thirdelectrical signal 102 d. - In one embodiment, the first
electrical signal 101 a is a single-ended signal, wherein a pin of the single-chipintegrated circuit 100 is used for inputting the firstelectrical signal 101 a. - In one embodiment, the first
electrical signal 101 a is a pair of differential signals, wherein two pins of the single-chipintegrated circuit 100 are used for inputting the pair of differential signals. - In one embodiment, the second
electrical signal 102 a is a single-ended signal, wherein a pin of the single-chipintegrated circuit 100 is used for inputting the secondelectrical signal 102 a. - In one embodiment, the second
electrical signal 102 a is a pair of differential signals, wherein two pins of the single-chipintegrated circuit 100 are used for inputting the pair of differential signals. - In one embodiment, the third
electrical signal 102 d is a single-ended signal, wherein a pin of the single-chipintegrated circuit 100 is used for outputting the thirdelectrical signal 102 d. - In one embodiment, the third
electrical signal 102 d is a pair of differential signals, wherein two pins of the single-chipintegrated circuit 100 are used for outputting the pair of differential signals. - In one embodiment, the pair of differential signals is based on TMDS (Time Minimized Differential Signal) and conformed to HDMI standard.
- In one embodiment, the pair of differential signals is based on TMDS (Time Minimized Differential Signal) and conformed to DP standard.
- In one embodiment, each of the second
electrical signal 102 a and the thirdelectrical signal 102 d is a single-ended signal. - In one embodiment, wherein each of the second
electrical signal 102 a and the thirdelectrical signal 102 d is a pair of differential signals. - In one embodiment, the second
electrical signal 102 a and the thirdelectrical signal 102 d are based on USB standard. - In one embodiment, an optical diode D1, such as a laser diode, is used for converting the first
electrical signal 101 a to the firstoptical signal 101 b. - In one embodiment, as shown in
FIG. 1A , the optical diode D1 is outside of the single-chipintegrated circuit 100. - In one embodiment, as shown in
FIG. 1B , the optical diode D1 is inside of the single-chipintegrated circuit 100. - In one embodiment, the optical diode D1 is a VCSEL (Vertical Cavity Surface Emitting Laser) diode.
- In one embodiment, an optical diode D2, such as a laser diode, is used for converting the second
electrical signal 102 a to the secondoptical signal 102 b and a photo diode D3 is used for converting the thirdoptical signal 102 c to the thirdelectrical signal 102 d. - In one embodiment, the optical diode D2 is a VCSEL (Vertical Cavity Surface Emitting Laser) diode.
- In one embodiment, as shown in
FIG. 1A , the diodes D2 and D3 are outside of theintegrated circuit 100. - In one embodiment, as shown in
FIG. 1B , the diodes D2 and D3 are inside of theintegrated circuit 100. - In one embodiment, the at least one
unidirectional communication channel 101 is used for transmitting video data and the at least onebidirectional communication channel 102 is used for transmitting and receiving control data associated with the video data. - In one embodiment, the at least one
unidirectional communication channel 101 is used for transmitting HDMI video data and the at least onebidirectional communication channel 102 is used for transmitting and receiving HDMI control data associated with the HDMI video data. - In one embodiment, the at least one
unidirectional communication channel 101 is used for transmitting DP video data and the at least onebidirectional communication channel 102 is used for transmitting and receiving DP control data associated with the DP video data. - In one embodiment, the single-chip
integrated circuit 100 is based on CMOS technology. - In one embodiment, the single-chip
integrated circuit 100 comprises a plurality of unidirectional communication channels, wherein each unidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal. - In one embodiment, the single-chip
integrated circuit 100 comprises a plurality of bidirectional communication channels, wherein each bidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a corresponding sub-circuit for converting a corresponding optical signal to a corresponding electrical signal. - In one embodiment, each
unidirectional communication channel 101 transmits 12 Gbps signal. - In one embodiment, each
unidirectional communication channel 101 transmits 6 Gbps signal. - In one embodiment, each
bidirectional communication channel 102 transmits and receives 480 Mbps signal. - In one embodiment, each
bidirectional communication channel 102 transmits and receives 10 Gbps signal. - In one embodiment, each
bidirectional communication channel 102 transmits and receives 20 Gbps signal. - In one embodiment, the single-chip
integrated circuit 100 comprises four unidirectional communication channels and one bidirectional communication channel. - In one embodiment, the single-chip
integrated circuit 100 comprises four unidirectional communication channels and two bidirectional communication channels. - In one embodiment, as shown in
FIG. 1C , the firstunidirectional communication channel 101 comprises afirst equalizer 101E and afirst output driver 101D, wherein the firstelectrical signal 101 a is coupled to an input of thefirst equalizer 101E and an output of thefirst equalizer 101E is coupled to an input of thefirst output driver 101D, wherein thefirst output driver 101D is coupled to a first optical diode D1 to generate the firstoptical signal 101 b. - In one embodiment, as shown in
FIG. 1D , the firstbidirectional communication channel 102 comprises afirst equalizer 102E and afirst output driver 102D, wherein the firstelectrical signal 102 a is coupled to an input of thefirst equalizer 102E and an output of thefirst equalizer 102E is coupled to an input of thefirst output driver 102D, wherein thefirst output driver 102D is coupled to a second optical diode D2 to generate the secondoptical signal 102 b. - In one embodiment, as shown in
FIG. 1D , the firstbidirectional communication channel 102 comprises anamplifier 102A, wherein an input of theamplifier 102A is coupled to a fourth electrical signal that is generated by the optical diode D3 in response to the thirdoptical signal 102 c, and an output of theamplifier 102A is coupled to the thirdelectrical signal 102 d. - In one embodiment, as shown in
FIG. 1D , the firstbidirectional communication channel 102 further comprises an input buffer 102B1 and an output buffer 102B2, wherein an input of the input buffer 102B1 is coupled to the fourth electrical signal generated by the optical diode D3 in response to the thirdoptical signal 102 c, and an output of the input buffer 102B1 is coupled to the input of theamplifier 102A, wherein an input of the output buffer 102B2 is coupled to the output of theamplifier 102A, and an output of theoutput buffer 102A is coupled to the thirdelectrical signal 102 d. -
FIG. 2 illustrates an example of the single-chipintegrated circuit 100, wherein the first unidirectional communication channel receives a pair of differential signals D1_in+, D1_in− that is coupled to afirst equalizer 101E, wherein thefirst equalizer 101E is inputted to afirst output driver 101D and thefirst output driver 101D outputs a first pair of differential signal VCSEL1, CC1 to drive a first laser diode LD1; the second unidirectional communication channel receives a second pair of differential signals D2_in+, D2_in− that is coupled to a second equalizer, wherein the second equalizer is inputted to a second output driver and the second output driver outputs a second pair of differential signal VCSEL2, CC2 to drive a second laser diode LD2; the third unidirectional communication channel receives a third pair of differential signals D3_in+, D3_in− that is coupled to a third equalizer, wherein the third equalizer is inputted to a third output driver and the third output driver outputs a third pair of differential signal VCSEL3, CC3 to drive a third laser diode LD3; the fourth unidirectional communication channel receives a fourth pair of differential signals D4_in+, D4_in− that is coupled to a fourth equalizer, wherein the fourth equalizer is inputted to a fourth output driver and the fourth output driver outputs a fourth pair of differential signal VCSEL4, CC4 to drive a fourth laser diode LD4. The first bidirectional communication channel receives a pair of differential signals D5_in+, D5_in− that is coupled to a fifth equalizer, wherein the fifth equalizer is inputted to a fifth output driver and the fifth output driver outputs a fifth pair of differential signal VCSEL5, CC5 to drive a fifth laser diode LD5; the first bidirectional communication channel receives a pair of differential signals PINK6, PINA6 that is generated form the photo diode PD6 and coupled to an input buffer, wherein the input buffer 102B1 is inputted to an input of anamplifier 102A and an output of theamplifier 102A is inputted to an output buffer 102B2, wherein the output buffer 102B2 outputs a sixth pair of differential signals D6_in+, D6_in−. - In one embodiment, each of the laser diodes D1, D2, D3, D4, D5 is a VCSEL (Vertical Cavity Surface Emitting Laser) diode.
- The single-chip integrated circuit in
FIG. 2 is based on CMOS technology. -
FIG. 3A illustrates a single-chipintegrated circuit 300, wherein single-chipintegrated circuit 300 comprises: at least one firstunidirectional communication channel 301, wherein the firstunidirectional communication channel 301 comprises a first sub-circuit for converting a firstoptical signal 301 b to a firstelectrical signal 301 a; and at least one firstbidirectional communication channel 302, wherein the first bidirectional communication channel comprises a second sub-circuit for converting a secondelectrical signal 302 a to a secondoptical signal 302 b and a third sub-circuit for converting a thirdoptical signal 302 c to a thirdelectrical signal 302 d. - In one embodiment, a pin of the single-chip
integrated circuit 300 is used for outputting the firstelectrical signal 301 a, wherein the firstelectrical signal 301 a is a single-ended signal. - In one embodiment, the first
electrical signal 301 a is a pair of differential signals, wherein two pins of the single-chipintegrated circuit 300 are used for outputting the pair of differential signals. - In one embodiment, the pair of differential signals is based on TMDS (Time Minimized Differential Signal) and conformed to HDMI standard.
- In one embodiment, the pair of differential signals is based on TMDS (Time Minimized Differential Signal) and conformed to DP standard.
- In one embodiment, the second
electrical signal 302 a and the thirdelectrical signal 302 d are based on USB standard. - In one embodiment, each of the second
electrical signal 302 a and the thirdelectrical signal 302 d is a single-ended signal. - In one embodiment, wherein each of the second
electrical signal 302 a and the thirdelectrical signal 302 d is a pair of differential signals. - In one embodiment, as shown in
FIG. 3A , a photo diode D4 used for converting the firstoptical signal 301 b to the firstelectrical signal 301 a is outside of the single-chipintegrated circuit 300. - In one embodiment, as shown in
FIG. 3B , the photo diode D4 used for converting the firstoptical signal 301 b to the firstelectrical signal 301 a is inside of the single-chipintegrated circuit 300. - In one embodiment, an optical diode D2, such as a laser diode, is used for converting the second
electrical signal 302 a to the secondoptical signal 302 b and a photo diode D3 is used for converting the thirdoptical signal 302 c to the thirdelectrical signal 302 d. - In one embodiment, the optical diode D2 is a VCSEL (Vertical Cavity Surface Emitting Laser) diode.
- In one embodiment, as shown in
FIG. 3A , the diodes D2 and D3 are outside of theintegrated circuit 300. - In one embodiment, as shown in
FIG. 3B , the diodes D2 and D3 are inside of theintegrated circuit 300. - In one embodiment, the first unidirectional communication channel is used for transmitting video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the video data.
- In one embodiment, the at least one unidirectional communication channel is used for transmitting HDMI video data and the at least one bidirectional communication channel is used for transmitting and receiving HDMI control data associated with the HDMI video data.
- In one embodiment, the at least one unidirectional communication channel is used for transmitting DP video data and the at least one bidirectional communication channel is used for transmitting and receiving DP control data associated with the DP video data.
- In one embodiment, the single-chip
integrated circuit 300 is based on CMOS technology. - In one embodiment, the single-chip
integrated circuit 300 comprises a plurality of unidirectional communication channels. - In one embodiment, the single-chip
integrated circuit 300 comprises a plurality of bidirectional communication channels. - In one embodiment, the
unidirectional communication channel 301 receives 12 Gbps optical signal. - In one embodiment, the
unidirectional communication channel 301 receives 6 Gbps optical signal. - In one embodiment, the
bidirectional communication channel 302 transmits and receives 480 Mbps optical signal. - In one embodiment, the
bidirectional communication channel 302 transmits and receives 10 Gbps optical signal. - In one embodiment, the
bidirectional communication channel 302 transmits and receives 20 Gbps optical signal. - In one embodiment, the single-chip
integrated circuit 300 comprises four unidirectional communication channels and one bidirectional communication channel. - In one embodiment, the single-chip
integrated circuit 300 comprises four unidirectional communication channels and two bidirectional communication channels. - In one embodiment, as shown in
FIG. 3C , the firstunidirectional communication channel 301 comprises anamplifier 301A, wherein an input of theamplifier 301A is coupled to a fourthelectrical signal 301 e that is generated by a photo diode D4 in response to the firstoptical signal 301 b, and an output of theamplifier 301A is coupled to the firstelectrical signal 301 a. - In one embodiment, as shown in
FIG. 3C , the firstbidirectional communication channel 301 further comprises an input buffer 301B1 and an output buffer 301B2, wherein an input of the input buffer 301B1 is coupled to the fourthelectrical signal 301 e that is generated by the photo diode D4 in response to the firstoptical signal 301 b, and an output of the input buffer 301B1 is coupled to the input of theamplifier 301A, wherein an input of the output buffer 301B2 is coupled to the output of theamplifier 301A, and an output of the output buffer 301B2 is coupled to firstelectrical signal 301 a. - In one embodiment, as shown in
FIG. 3D , the firstbidirectional communication channel 302 comprises afirst equalizer 302E and afirst output driver 302D, wherein the firstelectrical signal 302 a is coupled to an input of thefirst equalizer 302E and an output of thefirst equalizer 302E is coupled to an input of thefirst output driver 302D, wherein thefirst output driver 302D is coupled to a second optical diode D2 to generate the secondoptical signal 302 b. - In one embodiment, as shown in
FIG. 3D , the firstbidirectional communication channel 302 comprises anamplifier 302A, wherein an input of theamplifier 302A is coupled to anelectrical signal 302 e that is generated by the photo diode D3 in response to the thirdoptical signal 302 c, and an output of theamplifier 302A is coupled to the thirdelectrical signal 302 d. - In one embodiment, as shown in
FIG. 3D , the firstbidirectional communication channel 302 further comprises an input buffer 302B1 and an output buffer 302B2, wherein an input of the input buffer 302B1 is coupled to theelectrical signal 302 e that is generated by the photo diode D3 in response to the thirdoptical signal 302 c, and an output of the input buffer 302B1 is coupled to the input of theamplifier 302A, wherein an input of the output buffer 302B2 is coupled to the output of theamplifier 302A, and an output of theoutput buffer 302A is coupled to the thirdelectrical signal 302 d. -
FIG. 4 illustrates an example of the single-chip integrated circuit 300, wherein the first unidirectional communication channel receives a pair of differential signals PINK1, PINA1 generated form the photo diode PD1 and coupled to an input buffer 301B1, wherein the input buffer 301B1 is inputted to an input of an amplifier 301A and an output of the amplifier 301A is inputted to an output buffer 301B2, wherein the output buffer 301B2 outputs a pair of differential signals out1 +, out1 −; the second unidirectional communication channel receives a pair of differential signals PINK2, PINA2 generated form the photo diode PD2 and coupled to an input buffer, wherein the input stage buffer is inputted to an input of an amplifier and an output of the amplifier is inputted to an output buffer, wherein the output buffer outputs a pair of differential signals out2 +, out2; the third unidirectional communication channel receives a pair of differential signals PINK3, PINA3 generated form the photo diode PD3 and coupled to an input buffer, wherein the input stage is inputted to an input of an amplifier and an output of the amplifier is inputted to an output buffer, wherein the output buffer outputs a pair of differential signals out3 +, out3; the fourth unidirectional communication channel receives a fourth pair of differential signals PINK4, PINA4 generated form the photo diode PD4 and coupled to an input buffer, wherein the input buffer is inputted to an input of an amplifier and an output of the amplifier is inputted to an output buffer, wherein the output buffer outputs a pair of differential signals out4 +, out4. The first bidirectional communication channel receives a pair of differential signals PINK5, PINA5 generated form the photo diode PD5 and coupled to an input buffer 302B1, wherein the input buffer 302B1 is inputted to an input of anamplifier 302A and an output of theamplifier 302A is inputted to an output buffer 302B2, wherein the output buffer 302B2 outputs a pair of differential signals out5 +, out5 −; the first bidirectional communication channel receives a pair of differential signals D6_in+, D6_in− that is coupled to anequalizer 302E, wherein theequalizer 302E is inputted to anoutput driver 302D and theoutput driver 302D outputs a pair of differential signal VCSEL6, CC6 to drive the laser diode LD6. - In one embodiment, each laser diode LD1, LD2, LD3, LD4, LD6 is a VCSEL (Vertical Cavity Surface Emitting Laser) diode.
-
FIG. 5 illustrates an example of a communication system using the single-chipintegrated circuit 100 and the single-chipintegrated circuit 300, wherein the single-chipintegrated circuit 100 and the single-chipintegrated circuit 300 are connected by six fibers, wherein the four unidirectional channel of the single-chipintegrated circuit 100 are used for transmitting HDMI TMDS video, and the four unidirectional channel of the single-chipintegrated circuit 300 are used for receiving the HDMI TMDS video. The USB bidirectional channel of the single-chipintegrated circuit 100 and the USB bidirectional channel of the single-chipintegrated circuit 300 are used for transmitting and receiving control data associated with the HDMI TMDS video data. The four unidirectional HDMI TMDS channels can be 4×6 Gbps (HDMI 2.0) or 4×12 Gbps (HDMI 2.1). The USB bidirectional channel can be 1×480 Mbps (USB 2) or 1×10 G bps (USB 3) or 1×20 G bps (USB 4). The advantages ofFIG. 6 includes: Low cost AOC with minimum VCSEL/PD chip count, designed for cost effective 6 fiber cable application, free from EMI interference, high bandwidth, low signal loss, which is suitable for applications such as NB docking station, high speed light weight VR headset or gaming console connection. -
FIG. 6 illustrates an example of a communication system using the single-chipintegrated circuit 100 and the single-chipintegrated circuit 300, wherein the single-chipintegrated circuit 100 and the single-chipintegrated circuit 300 are connected by six fibers, wherein the four DP TMDS unidirectional channel of the single-chipintegrated circuit 100, are used for transmitting DP video data, and the four DP TMDS unidirectional channel of the single-chipintegrated circuit 300 are used for receiving the DP video data. the USB bidirectional channel of the single-chipintegrated circuit 100 and the USB bidirectional channel of the single-chipintegrated circuit 300 are used for transmitting and receiving control data associated with the DP video data. The four DP TMDS unidirectional channels can be 8.1 Gbps (DP1.4) or 4×20 Gbps (DP2.0). The USB bidirectional channel can be 1×480 Mbps (USB 2) or 1×10 G bps (USB 3) or 1×20 G bps (USB 4). The advantages of the communication system inFIG. 7 includes: low cost AOC with minimum VCSEL/PD chip count, designed for cost effective 6 fiber cable application, free from EMI interference, high bandwidth, low signal loss, which is suitable for applications such as NB docking station, high speed light weight VR headset or gaming console connection. -
FIG. 7 illustrates an example of a communication system using the single-chipintegrated circuit 100 and the single-chipintegrated circuit 300, wherein the single-chipintegrated circuit 100 and the single-chipintegrated circuit 300 are connected by six fibers, wherein the four unidirectional channel of the single-chipintegrated circuit 100 are used for transmitting HDMI TMDS video, and the four unidirectional channel of the single-chipintegrated circuit 300 are used for receiving the HDMI TMDS video. Two USB bidirectional channels of the single-chipintegrated circuit 100 and the two USB bidirectional channel of the single-chipintegrated circuit 300 are used for transmitting and receiving control data associated with the HDMI TMDS video data. The four HDMI TMDS unidirectional channels can be 4×6 Gbps (HDMI 2.0) or 4×12 Gbps (HDMI 2.1). The two USB bidirectional channels can be 2×480 Mbps (USB 2) or 2×10 G bps (USB 3) or 2×20 G bps (USB 4). The advantages of the communication system inFIG. 8 includes: low cost AOC with minimum VCSEL/PD chip count, designed for cost effective 8 fiber cable application, free from EMI interference, high bandwidth, low signal loss, which is suitable for applications such as NB docking station, high speed light weight VR headset or gaming console connection. -
FIG. 8 illustrates an example of a communication system using the single-chipintegrated circuit 100 and the single-chipintegrated circuit 300, wherein the single-chipintegrated circuit 100 and the single-chipintegrated circuit 300 are connected by six fibers, wherein the four unidirectional channel of the single-chipintegrated circuit 100 are used for transmitting DP TMDS video, and the four unidirectional channel of the single-chipintegrated circuit 300 are used for receiving the DP TMDS video. Two USB bidirectional channels of the single-chipintegrated circuit 100 and the two USB bidirectional channel of the single-chipintegrated circuit 300 are used for transmitting and receiving control data associated with the DP TMDS video data. The four DP TMDS unidirectional channels can be 4×8.1 Gbps (DP1.4) or 4×20 Gbps (DP2.0). The two USB bidirectional channels can be 2×480 Mbps (USB 2) or 2×10 G bps (USB 3) or 2×20 G bps (USB 4). The advantages of the communication system inFIG. 9 includes: low cost AOC with minimum VCSEL/PD chip count, designed for cost effective 8 fiber cable application, free from EMI interference, high bandwidth, low signal loss, which is suitable for applications such as NB docking station, high speed light weight VR headset or gaming console connection. -
FIG. 9 illustrates an example of a communication system using the single-chipintegrated circuit 100 and the single-chipintegrated circuit 300, wherein the single-chipintegrated circuit 100 and the single-chipintegrated circuit 300 are connected by six fibers, wherein the four unidirectional channel of the single-chipintegrated circuit 100 are used for transmitting HDMI TMDS video, and the four unidirectional channel of the single-chipintegrated circuit 300 are used for receiving the HDMI TMDS video. Two USB bidirectional channels of the single-chipintegrated circuit 100 and the two USB bidirectional channel of the single-chipintegrated circuit 300 are used for transmitting and receiving control data associated with the HDMI TMDS video data. The four HDMI TMDS unidirectional channels can be 4×6 Gbps (HDMI 2.0) or 4×12 Gbps (HDMI 2.1). The two bidirectional channels includes one eARC bidirectional channel and one I2C bidirectional channel. The eARC bidirectional channel can be used for HDMI 2.1 eARC reverse audio signal transmission. The I2C bidirectional channel can be used for HDMI 2.1 I2C data transmission. The advantages of the communication system inFIG. 10 includes: low cost AOC with minimum VCSEL/PD chip count, designed for cost effective 8 fiber cable application, free from EMI interference, high bandwidth, low signal loss, which is suitable for optical HDMI 2.1 AOC application. - The foregoing descriptions of specific embodiments of the present invention have been presented for purposes of illustrations and description. They are not intended to be exclusive or to limit the invention to the precise forms disclosed, and obviously many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical application, to thereby enable others skilled in the art to best utilize the invention and various embodiments with various modifications as are suited to particular use contemplated. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.
Claims (20)
1. a single-chip integrated circuit with asymmetric optical communication architecture, comprising: at least one first unidirectional communication channel, wherein the first unidirectional communication channel comprises a first sub-circuit for converting a first electrical signal to a first optical signal; and at least one first bidirectional communication channel, wherein the first bidirectional communication channel comprises a second sub-circuit for converting a second electrical signal to a second optical signal and a third sub-circuit for converting a third optical signal to a third electrical signal.
2. The single-chip integrated circuit of claim 1 , wherein the first unidirectional communication channel is used for transmitting video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the video data.
3. The single-chip integrated circuit of claim 1 , wherein the first sub-circuit comprises a first equalizer and a first output driver, wherein the first electrical signal is coupled to an input of the first equalizer and an output of the first equalizer is coupled to an input of the first output driver, wherein the first output driver is coupled to a first optical diode to generate the first optical signal.
4. The single-chip integrated circuit of claim 1 , wherein the second sub-circuit comprises a second equalizer and a second output driver, wherein the second electrical signal is coupled to an input of the second equalizer and an output of the second equalizer is coupled to an input of the second output driver, wherein the second output driver is coupled to a second optical diode to generate the second optical signal.
5. The single-chip integrated circuit of claim 1 , wherein the third sub-circuit comprises an amplifier, wherein an input of the amplifier is coupled to a photo diode that generates a fourth electrical signal in response to the third optical signal, wherein the input of the amplifier is coupled to the fourth electrical signal and an output of the amplifier is coupled to the third electrical signal.
6. The single-chip integrated circuit of claim 1 , wherein the first electrical signals is a pair of differential signals.
7. The single-chip integrated circuit of claim 1 , wherein each of the second electrical signal and the third electrical signal is a pair of differential signals.
8. The single-chip integrated circuit of claim 1 , wherein the at least one unidirectional communication channel is used for transmitting HDMI video data and the at least one bidirectional communication channel is used for transmitting and receiving control data associated with the HDMI video data.
9. The single-chip integrated circuit of claim 1 , wherein the at least one unidirectional communication channel is used for transmitting DP video data and the at least one bidirectional communication channel is used for transmitting and receiving control data associated with the DP video data.
10. The single-chip integrated circuit of claim 1 , wherein each of the second electrical signal and third electrical signal is based on USB standard.
11. The single-chip integrated circuit of claim 1 , wherein the single-chip integrated circuit is based on CMOS technology.
12. The single-chip integrated circuit of claim 1 , wherein the single-chip integrated circuit comprises a plurality of unidirectional communication channels and a plurality of bidirectional communication channels, wherein each unidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal, and wherein each bidirectional communication channel comprises a corresponding sub-circuit for converting a corresponding electrical signal to a corresponding optical signal and a corresponding third sub-circuit for converting a corresponding optical signal to a corresponding electrical signal.
13. A single-chip integrated circuit with asymmetric optical communication architecture, comprising:
at least one first unidirectional communication channel, wherein the first unidirectional communication channel comprises a first sub-circuit for converting a first optical signal to a first electrical signal; and
at least one first bidirectional communication channel, wherein the first bidirectional communication channel comprises a second sub-circuit for converting a second electrical signal to a second optical signal and a third sub-circuit for converting a third optical signal to a third electrical signal.
14. The single-chip integrated circuit of claim 13 , wherein the first unidirectional communication channel is used for receiving video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the video data.
15. The single-chip integrated circuit of claim 13 , wherein the first unidirectional communication channel is used for transmitting HDMI video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the HDMI video data.
16. The single-chip integrated circuit of claim 13 , wherein the first unidirectional communication channel is used for transmitting DP video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the DP video data.
17. The single-chip integrated circuit of claim 13 , wherein each of the second electrical signal and third electrical signal is based on USB standard.
18. The single-chip integrated circuit of claim 13 , wherein the single-chip integrated circuit is based on CMOS technology.
19. A circuit with asymmetric optical communication architecture, comprising: at least one first unidirectional communication channel, wherein the first unidirectional communication channel comprises a first sub-circuit for converting a first electrical signal to a first optical signal; and at least one first bidirectional communication channel, wherein the first bidirectional communication channel comprises a second sub-circuit for converting a second electrical signal to a second optical signal and a third sub-circuit for converting a third optical signal to a third electrical signal, wherein the first unidirectional communication channel is used for transmitting video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the video data.
20. The circuit of claim 19 , wherein the first unidirectional communication channel is used for transmitting HDMI video data and the first bidirectional communication channel is used for transmitting and receiving control data associated with the HDMI video data.
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US17/127,898 US20220200827A1 (en) | 2020-12-18 | 2020-12-18 | Asymmetric Optical Communication Architecture |
CN202110280760.2A CN114650399A (en) | 2020-12-18 | 2021-03-16 | Asymmetric optical communication framework |
TW110109390A TWI840658B (en) | 2020-12-18 | 2021-03-16 | A single-chip integrated circuit with asymmetric optical communication architecture |
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US17/127,898 US20220200827A1 (en) | 2020-12-18 | 2020-12-18 | Asymmetric Optical Communication Architecture |
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US20120249240A1 (en) * | 2011-03-29 | 2012-10-04 | Sony Corporation | System and method for effectively implementing a front end for a transimpedance amplifier |
US20140049292A1 (en) * | 2012-08-17 | 2014-02-20 | Ati Technologies Ulc | Integrated circuit package having medium-independent signaling interface coupled to connector assembly |
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TWI840658B (en) | 2024-05-01 |
TW202226775A (en) | 2022-07-01 |
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